DE19744457C1 - Remote operator with motor for circuit breaker - Google Patents

Description

The invention relates to a motor drive for electrical Switchgear intended especially for circuit breakers is. The coupling of the drive to the circuit breaker is possible via the toggle or the switch lock.

To get optimal equipment and build as narrow as possible, is a coupling on the gag makes sense. These are Motoran gearbox, which announced a snap-in power cause switch. These are u. a. in the pamphlets FR 24 76 896, EP 0 034 966 A1, EP 0 150 756 A2 and EP 0 506 066 B1. These drives are relatively up manoeuvrable. In contrast, motor drives are simpler Design for circuit breakers, which themselves a Sprungeinschal owning. In the document DE 690 24 176 T2 is one of described similar drive. These are for circuit breakers without jumping mechanism usually unsuitable, since the Switching speed is too small. The remote drives will be are mostly screwed onto the circuit breaker and are specifically for the characteristics of each switch placed. For controlling the motor drive by a PLC, the operating current should be kept as small as possible the. As a result, an operation via solenoid or as in EP 0 506 066 B1 triggering of a latching over Off Solenoid magnet adversely. A manual operation must be possible at any time be.

The invention is based on the object, a motor drive for electrical switching devices, in particular for power switch so that it can be used for different Shen with different switching characteristics under Be taking into account the necessary safety measures minimal power consumption and simple design applied who that can.  

This object is achieved in a drive with motor according to the preamble of claim 1 according to the invention in that the circuit breaker 3 is screwed onto a frame 19 ( Fig. 7). The individual parts of the drive blocks 17 , 18 are mounted between or on the boards 20 , 21 and are placed on the toggle 2 of the circuit breaker 3 , screwed to the frame 19 and covered with a cap 39 . The remote operator is connected via a connector to the supply voltages and the command devices for the actuation. The adaptation to multiple sizes of circuit breakers is done by different frame 19 in combination with various types of drive blocks 17 , 18 with and without jump function. In this case, the basic structure is the same, by replacing or eliminating fewer parts arise different drive blocks. Fig. 1 shows the top view of a drive block with jump function. The gear coupling 1 , 27 , 31 with the geared motor 15 ( FIGS. 3-5 and 7) can be seen. The lateral basic structure is shown in FIG. 8. In this case, the driver 4 can be seen, which serves as a bearing axis of the output gear 1 , support lever 8 and toggle 25 and between the boards 20 , 21 is mounted.

The latching system is formed by torsion spring 5 , pin 7 on the output gear 1 and half shaft 44 , wherein the torsion spring 5 is mounted biased on the output gear 1 and is supported on the pin 7 .

Fig. 2 shows the top view of a drive block 17 without snap on, with respect to the drive block 18 , torsion spring 5 , support lever 8 and half shaft 44 omitted and a resilient driver 47 is added. In Figs. 3 and 4, the structure of the drive blocks 17 and 18 is shown. The motor drive is supplemented by a pivoting system with the parts 26 , 28 , 29 , 30 , 32 , 33 for mechanical decoupling of the gears and electrical separation in manual operation, a jump system 12 , 13 ( Fig. 5) for switching the engine (reversing) and a locking system 23 ( Figure 6). In this case, the pivot system and the locking system 23 are coupled together, in which a closure of the knob 25 is only possible in the OFF position of the circuit breaker 3 with mechanical and electrical separation of the motor drive.

At the same time, the cap 39 is connected to the latch 38 , 42 with its hook 43 ( FIG. 7). A removal of the cap is only possible with mechanical and electrical separation of the device. This combination saves limit switches.

A comparison shows the following picture:

Motor drive according to the invention Conventional variant 1 limit switch 1 limit switch cap 1 limit switch closing @ 1 limit switch electrical disconnection with mechanical separation

In Fig. 7, the entire motor drive with circuit breaker 3 is shown.

Preferred embodiments of the invention are illustrated in the drawings.

Fig. 1 top view drive block with snap-on upper board removed

Fig. 2 top view drive block removed without snap-on upper board

Fig. 3 side view of drive block with snap on

Fig. 4 side view of drive block without snap on

Fig. 5 Bottom view of the drive block with and without snap-on activation (jump system)

Fig. 6 top view of the drive block with an upper plate (lock system)

Fig. 7 side view drive block with frame and circuit breaker

Fig. 8 side view of the principle of snap-on engagement (pawl system)

Based on these representations, the functional sequence is described.

A geared motor 15 on the pivoting lever 26 with pinion 27 which can be swung in the event of a fault for a manual operation with the eccentric 34, 35 from the gear engagement (distance (a). Fig. 1 and 2) drives, via a coupling gear 31, a driven gear 1 on, on an axis (driver 4 ) with the circuit breaker 3 to be switched ( Fig. 7) sits. The driver 4 of the drive block 17 or 18 engages the toggle 2 of the circuit breaker 3 and has a similar toggle 25 with a locking mechanism 23 (lockable) for the manual operation and the switch position display. Both actuating toggle 2 , 25 are rigidly coupled together in the direction of rotation. The actuating knob 2 of the circuit breaker 3 with internal snap-action switching is rotated by the output gear 1 via a loose and resilient coupling in the respective desired switching direction ON or OFF. Does this circuit breaker z. B. reaches its Einschaltsprungpunkt in the direction of ON, he can turn on unhindered. The motor drive continues even in this direction, until the jump system 13 of the motor drive ( Fig. 5), actuated by lugs 11 on the output gear 1 , on lug 12, the motor rotation direction changes. In this case, the driver 47 in Fig. 2 resiliently against the driver 4 and thus against the gag 2 . The on or off position is reached safely. This is all the more important when the circuit breaker 3 is tripped, because the safe relocking requires it.

By reversing the motor 15 via the limit switches 37 in Fig. 4, 5, 7, the output gear 1 is returned to the starting position, so that the recess 55 again above each other and the current setting 54 of the circuit breaker 3 ( Fig. 1, 2) visible and operable as well as a manual connection is possible. The shutdown takes place via the limit switch 16 .

The circuit breaker 3 without snap-action engagement ( Figs. 2, 4) is operated similarly, but the switching is effected by means of a preloaded spring and a latch system ( Fig. 8). By simple and minor modification of the system 17 in FIG. 18, the adaptation to a circuit breaker 3 is achieved without a snap-in connection.

The output gear 1 with torsion spring 5 , 6 and support lever 8 ( Fig. 1, 8) is driven to Verklinkungsstelle 9 . At this point, the torque of the torsion spring 5 is transmitted from the pin 7 of the output gear 1 on the support lever 8 , the spring is further tensioned by the geared motor. Another pin 10 on the output gear 1 triggers in the further movement of this gear 1, the latch, in which case the moment of the spring 5 is transmitted to the driver 4 and thus the circuit breaker 3 turns on.

In the further course, then the torsion spring 5 takes over the resilient caster to switch the jumping system of FIG. 5. After switching the system goes back to the starting position. For the torsion spring applies:

M _{Torsion spring} <M _{Circuit breaker}

Thus, an adjustment of the moments on the spring is possible.

In the initial position, in which the output gear 1 is returned after each command execution, the knob 25 of the motor drive can be switched at any time by hand. In this case, the motor drive is automatically tracked and thus meets the condition dominating OFF. This is achieved by the limit switch 53 , which is actuated by the deformation 52 of the reset lever 49 and is connected in parallel to the ON button. In case of failure, ie power failure during a switching operation in the motor drive the gear motor 15 must be pivoted by means of the arranged in the cap 39 tool for the operation of the changeover pin 36 ( Fig. 7) in the position "Manual" for a manual operation. Only in this position, the cap 39 can be removed and the locking and closing of the knob, as described done.

The motor drive further includes a button 24 with screw 51 for resetting the alarm switch 50 for short tripping. In the delivery state, this reset takes place automatically when the circuit breaker 3 is tripped or when the RESET function is triggered. If this is not desired by the user, he can disable this automatic by removing the screw 51 in the reset button 24 . The electronic control of the process is on a circuit board 56 which is mounted between the boards 20 , 21 housed.

With the arrangement according to the invention, an adaptation to various power switches 3 having different switching characteristics has been achieved with the lowest power consumption. The used jump system works without adjustment.

Claims (20)

1. Motor drive with gear ratio and snap engagement for electrical switching devices, in particular circuit breaker, with actuation by a rotary knob and with a driving force transmitting carrier, which engages over the toggle, characterized in that the output gear ( 1 ) centered on the toggle ( 2 ) of a circuit breaker ( 3 ) to a driver ( 4 ) which engages through the output gear ( 1 ) and connects to the toggle ( 2 ) and the manual operation, is mounted and the output gear ( 1 ) receives a prestressed spring ( 5 ) whose movable end ( 6 ) is supported on a pin ( 7 ) of the output gear ( 1 ) and at the same time in a support lever ( 8 ), which is also mounted as the driven gear ( 1 ) on the driver ( 4 ), and at the beginning of the switch-on the driver ( 4 ) and the support lever ( 8 ) leads to a Verklinkungsstelle ( 9 ), where the biasing force of the spring ( 5 ) from the pin ( 7 ) of the driven gear ( 1 ) on the supported support lever ( 8 ) passes and the output gear ( 1 ) continues to rotate alone, the spring ( 5 ) continues to tension until another pin ( 10 ) of the output gear ( 1 ) the latch ( 9 ) solves and the torque of the spring ( 5 ) on the driver ( 4 ) transmits, which turns on the power switch ( 3 ) and then the output gear ( 1 ) with the driver ( 47 ) resiliently against the toggle ( 2 ) of the circuit breaker ( 3 ) until a lug ( 11 ) of the driven gear ( 1 ) moves a lug ( 12 ) which actuates a non-adjusting skip system ( 13 ) which in turn actuates limit switches ( 14 ) which control the reversing operation of the geared motor ( 15 ) and driven gear (Fig. 1 ), whereby the elements driven gear ( 1 ), spring ( 5 ), support lever ( 8 ) are returned to the initial position until a limit switch ( 16 ) ends the switch-on and the switch-off analogous to the switch-on without jump function performs and this entire arrangement by minor modification of parts on a drive without snap on ( 17 ) is convertible, the function described above is maintained only without jump. 2. Motor drive according to claim 1, characterized in that the drive block ( 17 , 18 ) is detachably bolted to a frame ( 19 ) which serves as a screw-on plane a circuit breaker ( 3 ). 3. Motor drive according to claim 1, characterized in that the main functional parts between two boards ( 20 , 21 ) are mounted, a switching device ( 22 ) from manual to automatic mode with locking system ( 23 ) and ajustagefreies jump system ( 13 ) for reversing the geared motor ( 15 ). 4. Motor drive according to claim 1, characterized in that the drive block ( 17 , 18 ) has a button ( 24 ) for resetting a message block, which is also guided parallel to the driver between the boards ( 20 , 21 ) and a spring in the Starting position is held. 5. Motor drive according to claim 3, characterized in that the switching device ( 22 ) for mechanical and electrical separation with the locking system ( 23 ) for closing the toggle ( 25 ) is combined by the remote drive. 6. Motor drive according to claim 3 and 5, characterized in that a pivot lever ( 26 ) with geared motor ( 15 ) and drive gear ( 27 ) on a spacer bolt ( 28 ) is mounted and a spring ( 29 ) between the pivot lever ( 26 ) and another spacers (30) opposite to the first spacer bolt (28) is arranged acts on the pivot lever (26) having a moment, the pivot lever (26) opposite to the bearing point on the second spacer bolt (30) is supported. 7. Motor drive according to claim 6, characterized in that the resilient pivot lever ( 26 ) is designed in its basic position so that the support receives the entire force of the spring ( 29 ) and a distance a between the drive gear ( 27 ), and coupling gear ( 31 ) realized in a pure positive connection and the flank reaction force from the output gear ( 1 ) is smaller than that of the pivot system. 8. Motor drive according to claim 7, characterized in that the second spacing bolt ( 30 ) acts simultaneously as spring suspension of the spring ( 29 ) and as a support point ( 32 ) of the pivot lever ( 26 ). 9. Motor drive according to claim 3, 6-8, characterized in that the pivot lever ( 26 ) in the vicinity of the support point ( 32 ) has a slope ( 33 ), where a pin ( 34 ) of an eccentric ( 35 ) fixed with a reversing pin ( 36 ) is connected, when turning the switching pin ( 36 ) a mechanical separation and by a bridge on the pivot lever ( 15 ), which actuates a limit switch ( 37 ), which performs electrical isolation and the pivot lever ( 26 ) thereafter on the Spring ( 29 ) automatically keeps in the switched position and is automatically returned to the initial position when actuated. 10. Motor drive according to claim 3, 6-9, characterized in that on the switching pin ( 36 ) above the spring ( 29 ) a latch ( 30 ) is mounted, which prevents the removal of the cap ( 39 ) in automatic mode and in conjunction with a, on the upper board ( 20 ) of the drive block ( 17 , 18 ) mounted locking lever ( 40 ) in the automatic position prevents the withdrawal of a slide ( 41 ) in the knob ( 26 ) or in the position "Manual" permits. 11. Motor drive according to claim 10, characterized in that the bolt ( 38 ) has a projection ( 42 ) which engages in a hook ( 43 ) of the cap ( 39 ) or releases them. 12. Motor drive according to claim 11, characterized in that in the position manual operation closing the toggle ( 25 ) on the remote drive by pulling out the slide ( 41 ), which engages in the upper board ( 20 ) is possible with a lock, but about the locking lever ( 40 ) of the bolt ( 38 ) on the switching pin ( 36 ) can not be brought into position automatic and thus the electrical separation is maintained. 13. Motor drive according to claim 1, 3, 4, characterized in that by combination of the output gear ( 1 ) in conjunction with a support lever ( 8 ), a half-shaft ( 44 ) and a spring ( 5 ) from a drive without snap engagement ( 17 ) a drive with snap engagement ( 18 ) can be produced. 14. Motor drive according to claim 3, characterized in that after the switching on and off a tuning-free jumping system ( 13 ) is actuated, which initiates the Reversierbetrieb, wherein a lug ( 11 ) in the output gear ( 1 ) a tab ( 12 ) actuated on the opposite to the entrainment of a spring ( 45 ) between the tab ( 12 ) and a jump lever ( 46 ) is arranged, which is pulled after the switching operation of the circuit breaker ( 3 ) on the dead center of the jump lever ( 46 ) and the limit switch ( 14 ) actuated , 15. Motor drive according to claim 3 and 14, characterized in that the output gear ( 1 ) has resilient drivers ( 47 ) which actuate the driver ( 4 ) and allow that after the on or off the output gear ( 1 ) can continue to run to actuate the jumping system ( 13 ) of the geared motor ( 15 ). 16. Motor drive according to claim 15, characterized in that the drive block ( 18 ) with snap engagement only a resilient stop ( 48 ) for switching off the circuit breaker ( 3 ) is present and the torsion spring ( 5 ) assumes the function of the second resilient driver when switching. 17. Motor drive according to claim 4, characterized in that via a reset lever ( 49 ) which is mounted on the driver ( 4 ), in conjunction with the button ( 24 ) a reset of the Kurzschlußmeldebausteins ( 50 ), wherein the key ( 24 ) is provided with a screw ( 51 ) which forms the point of application of the reset lever ( 49 ) and after removing the device can be reset only by hand. 18. Motor drive according to claim 1, characterized in that the return lever ( 49 ) has a deformation ( 52 ) which actuates a limit switch ( 53 ) which is parallel to the ON button and thus brings the system in a position with a manual operation, that a trouble-free electrical operation is possible. 19. Motor drive according to claim 1, characterized in that the current setting ( 54 ) on the circuit breaker ( 3 ) in each switching position through the recess ( 55 ) in the boards ( 20 , 21 ) and the output gear ( 1 ) is accessible. 20. Motor drive according to claim 1, characterized in that the circuit board ( 56 ) with the controller on the drive block ( 17 , 18 ) is attached.